Inhibition of cyclin-dependent kinase activity triggers neuronal differentiation of mouse neuroblastoma cells.

Studies on the molecular mechanisms underlying neuronal differentiation are frequently performed using cell lines established from neuroblastomas. In this study we have used mouse N1E-115 neuroblastoma cells that undergo neuronal differentiation in response to DMSO. During differentiation, cyclin-dependent kinase (cdk) activities decline and phosphorylation of the retinoblastoma gene product (pRb) is lost, leading to the appearance of a pRb-containing E2F DNA-binding complex. The loss of cdk2 activity is due to a decrease in cdk2 abundance whereas loss of cdk4 activity is caused by strong association with the cdk inhibitor (CKI) p27KIP1 and concurrent loss of cdk4 phosphorylation. Moreover, neuronal differentiation can be induced by overexpression of p27KIP1 or pRb, suggesting that inhibition of cdk activity leading to loss of pRb phosphorylation, is the major determinant for neuronal differentiation.

Adenovirus serotype determines association and localization of the large E1B tumor antigen with cellular tumor antigen p53 in transformed cells.

The distribution and stability of the cellular tumor antigen p53 were studied in baby rat kidney cells transformed by region E1 sequences of nononcogenic adenovirus (Ad) type 5 (Ad5) or oncogenic type 12 (Ad12). In transformed cells expressing the large E1B T antigen of Ad5, p53 was associated with this T antigen. The complexed proteins were concentrated in a cytoplasmic body, which has been shown to consist of a cluster of 8-nm filaments (A. Zantema et al., Virology 142:44-58, 1985). In transformed cells expressing the E1B region of Ad12, however, no association between the viral large T antigen and p53 was detectable. In the latter case, both proteins were found almost exclusively in the nucleus. The stability of p53 in both Ad5- and Ad12-transformed cells was increased relative to that in primary cells or cells immortalized by the E1A region only. Thus, the increased stability of p53 in Ad-transformed cells is not caused by association with a viral T antigen, but it correlates with expression of E1B and with morphological transformation.

The adenovirus E1A-associated 300 kDa adaptor protein counteracts the inhibition of the collagenase promoter by E1A and represses transformation.

Adenovirus E1A proteins modulate the expression of a large variety of genes in transformed cells by either stimulating or repressing their promoters. For example, the E1A proteins inhibit the collagenase promoter, whereas they activate the c-jun promoter. Both effects are mediated through AP-1/ATF-binding sites. Repression of transcription of the collagenase gene requires the amino-terminus and conserved region 1 (CR1) of Ad5 E1A, two regions that are also crucial for interaction of E1A with the recently isolated transcriptional adaptor protein p300. We show here that overexpressed p300 can counteract the repressive effect of E1A on the collagenase promoter. Using the CREB-binding protein (CBP), which is highly homologous to p300, the same results were obtained. The domains in E1A required for binding to p300 are also essential for E1A-mediated cell transformation. We therefore tested the effect of p300 and CBP on the transforming potential of Ad5 E1 in baby rat kidney (BRK) cells. It was found that E1A-induced focus formation was strongly inhibited by overexpression of p300 or CBP. Moreover the BRK cell colonies, obtained after cotransfection with Ad5E1 and p300, could not be established. These results indicate that one of the mechanisms by which E1A modulates transcription and transforms cells is via transcriptional adaptors like p300 and CBP.

Phosphorylation of a specific cdk site in E2F-1 affects its electrophoretic mobility and promotes pRB-binding in vitro.

The E2F transcription factor family participates in growth control presumably through transcriptional activation of genes that promote entry into S phase. E2F activity is believed to be controlled across the cell cycle by association with various cellular proteins, including the product of the retinoblastoma gene (pRB). We find that E2F-1 proteins are heterogeneously phosphorylated in insect cells, as a result of which they migrate as a doublet on SDS-polyacrylamide gels. This electrophoretic shift is shown to be dependent upon specific phosphorylation of E2F-1 on serine-375 (S375), near the pRB-binding site. Phosphorylation on S375 also occurs in human cells. E2F-1 was most efficiently phosphorylated on this residue by cyclin A/cdk2 kinase, and to a lesser extent by cyclin A/cdk2, irrespective of the presence of the pRB-related p107 protein. Phosphorylation of E2F-1 on S375 greatly enhanced its affinity of pRB in vitro. These results suggest a novel way of regulating E2F-1 activity, namely by cell-cycle-dependent phosphorylation of this transcription factor.

Differentiation of P19 EC cells leads to differential modulation of cyclin-dependent kinase activities and to changes in the cell cycle profile.

The retinoblastoma gene product (pRb) is essential for normal embryonic development. Phosphorylation of pRb by cyclin dependent kinases (cdk's) is believed to be crucial for the regulation of its function. In this report we have studied the regulation of pRb and cdk's during in vitro differentiation of P19 embryonal carcinoma (EC) cells, as a model for early developmental processes. During EC cell differentiation, the synthesis of pRb is strongly induced. In addition, the phosphorylation state of induced pRb is modulated, yielding mainly underphosphorylated pRb. Concomitantly, the pRb kinases cdk2 and cdk4 are differentially regulated: cdk2 kinase activity is impaired, whereas cdk4 kinase activity is stimulated, due to an induction of cyclins D1 and D2. Furthermore, the DNA binding activity of E2F transcription factors is strongly impaired during differentiation and the number of cells in G1 is increased. Thus, P19 EC cell differentiation is accompanied by changes in cdk-activities, pRb regulation and E2F DNA-binding, resulting in the generation of cell types with an altered cell cycle profile.

Altered AP-1/ATF complexes in adenovirus-E1-transformed cells due to EIA-dependent induction of ATF3.

The adenovirus (Ad) E1A proteins alter the expression level and activity of AP-1/ATF transcription factors. Previously we have shown that in AdE1-transformed cells cJun is hyperphosphorylated in its N-terminal transactivation domain, which parallels enhanced transactivation function. To find out whether the interaction between cJun and other cellular proteins is altered, we have searched for proteins which would physically associate with cJun. In this report we show that in AdE1-transformed cells cJun specifically associates with two proteins of 21 and 23 kD. These proteins are not expressed at detectable levels in the parental cells or in cells transformed by oncogenes other than AdE1. The cJun-associated proteins represent different forms of the bZIP transcription factor ATF3, the human homolog of rat LRF1. The expression of ATF3 is induced in AdE1-transformed cells and is a direct effect of the expression of E1A. Through induction of ATF3 expression and the subsequent formation of cJun/ATF3 heterodimers, E1A alters the repertoire of AP-1/ATF factors and may thereby redirect the corresponding gene-expression program. Since the induction of ATF3 is a function of sequences within the transforming 12S-ElA protein, cJun/ATF3 complexes might be involved in establishing cellular transformation by AdE1A.

Co-regulated expression of junB and MHC class I genes in adenovirus-transformed cells.

The expression of the junB gene parallels the expression of the MHC class I genes in Adenovirus (Ad) transformed cells. In Ad12E1-transformed primary BRK cells both genes are transcriptionally repressed only when the 13S product of Ad12E1A is present. This indicates that repression of MHC class I and junB genes is a function of conserved region 3 (CR3) of the Ad12E1A protein. In Ad5-transformed BRK cells expression of these genes is unchanged. In established NRK cells, however, introduction of Ad12E1A does not cause repression of the MHC class I and junB genes, but in these cells Ad5E1A increases the expression of both MHC class I and junB. Using mutant Ad5E1A genes, it is shown that this activation is mediated by CR1. Introduction of a functional junB gene under the control of a heterologous promoter in Ad12E1-transformed BRK cells causes no increase in MHC class I expression. This demonstrates that the down-regulation of junB is not directly responsible for class I repression, but rather that both genes are coregulated by the Ad12E1 region.

The N-terminal transactivation domain of ATF2 is a target for the co-operative activation of the c-jun promoter by p300 and 12S E1A.

The adenovirus E1A proteins activate the c-jun promoter through two Jun/ATF-binding sites, jun1 and jun2. P300, a transcriptional coactivator of several AP1 and ATF transcription factors has been postulated to play a role in this activation. Here, we present evidence that p300 can control c-jun transcription by acting as a cofactor for ATF2: (1) Over-expression of p300 was found to stimulate c-jun transcription both in the presence and absence of E1A. (2) Like E1A, p300 activates the c-jun promoter through the junl and jun2 elements and preferentially activates the N-terminal domain of ATF2. (3) Co-immunoprecipitation assays of crude cell extracts indicate that endogenous p300/CBP(-like) proteins and ATF2 proteins are present in a multiprotein complex that can bind specifically to the jun2 element. We further demonstrate that the Stress-Activated-Protein-Kinase (SAPK) target sites of ATF2, Thr69 and Thr71 are not required for the formation of the p300/CBP-ATF2 multiprotein complex. These data indicate that E1A does not inhibit all transcription activation functions of p300, and, in fact, cooperates with p300 in the activation of the ATF2 N-terminus.

Induction of the mitogen-activated p70 S6 kinase by adenovirus E1A.

Adenovirus E1A proteins can transform primary cells in culture in conjunction with other oncogenes, such as E1B or activated ras. The modulation of various cell cycle regulators by E1A is thought to be involved in this transformation process. In this paper we show that E1A enhances the expression of the mitogen-inducible p70 S6 kinase (p70s6k), a kinase which is essential for G1 progression. p70s6k mRNA and protein levels are enhanced 3-4-fold in various E1A-expressing cell lines. Similarly, the activity of p70s6k is enhanced in E1A-expressing cells in a manner partially independent of enhanced expression of p70s6k. The induction of p70s6k correlates with the presence of conserved region 1 (CR1) of E1A and with morphological transformation by E1A. These results suggest that induction of p70s6k by E1A might be involved in transformation by E1A.

Increased cyclin A and decreased cyclin D levels in adenovirus 5 E1A-transformed rodent cell lines.

Adenovirus-(Ad)- E1A proteins carry two conserved domains (CR1 and CR2) required for transformation of primary rodent cells and essential for association with cellular proteins, including p105RB, p58cyclin A and p33cdk2. We show that in normal rat kidney 49F (NRK) cell lines expressing various mutant Ad5-E1A genes, CR2-, but not CR-1-, deletion mutants induce a typical transformed phenotype as characterized by morphology, absence of density arrest and loss of serum requirement. This indicates that induction of these transformed properties is a function of CR1. The fact that E1A proteins with deletions in CR2 show a greatly reduced association with RB, cyclin A and p33cdk2 suggests that these associations are dispensable for E1A-mediated transformation of NRK cells. Induction of the transformed properties is accompanied by a CR1-dependent increase in Proliferating Cell Nuclear Antigen and cyclin A gene expression. Elevated mRNA and protein levels of cyclin A were also found in Ad12-E1-transformed NRK cells but not in ras-transformed NRK cells. On the other hand, cyclin D expression is decreased in a CR1-dependent manner. Although Ad5-E1A proteins are sufficient to transform NRK cells, further deregulation of growth is obtained when Ad5-E1B proteins are co-expressed. One of the Ad5-E1B effects is the sequestration of the p53 protein into a cytoplasmic body containing the p53/Ad5-E1B-55 kD complex. Interestingly, in NRK cell lines expressing Ad5-E1B-55 kD, cyclin A could be detected not only in the nucleus but also in the cytoplasmic bodies. These results indicate that the deregulation of cell cycle control by the Adenovirus-E1 region may be due to a CR1-dependent alteration of the expression of cyclins A and D.

Ribosomal proteins L7/L12 of Escherichia coli. Localization and possible molecular mechanism in translation.

Experiments were performed in order to determine the minimal requirement for the proteins L7/L12 in polyphenylalanine synthesis and elongation factor EF-G-dependent GTP hydrolysis. Via reconstitution, ribosomal particles were prepared containing variable amounts of L7/L12. The L7/L12 content of these particles was carefully determined by the use of 3H-labelled L7/L12 and by radioimmunoassay. The activity of the particles was determined as a function of the L7/L12 content. Our results show that only one dimer of L7/L12 is required for full activity in EF-G-dependent GTP hydrolysis. On the other hand, two L7/L12 dimers are required for polyphenylalanine synthesis. In addition, we have determined the relation between the number of L7/L12 stalks, as observed by electron microscopy, and the L7/L12 content of the 50 S particles. Our interpretation of these results is that each ribosomal particle possesses two L7/L12 binding sites, each site being involved in binding one dimer. Binding of L7/L12 dimer in one site gives rise to formation of the L7/L12 stalk, whereas binding in the other site has no effect on the number of visible stalks.

Protein kinase C-alpha is an upstream activator of the IkappaB kinase complex in the TPA signal transduction pathway to NF-kappaB in U2OS cells.

Inactive nuclear factor kappaB (NF-kappaB) complexes are retained in the cytoplasm by binding to inhibitory proteins, such as IkappaBalpha. Various stimuli lead to phosphorylation and subsequent processing of IkappaBalpha in the 26S proteasome and import of the active NF-kappaB transcription factor into the nucleus. In agreement with our previous finding that p90(rsk1) is essential for TPA-induced activation of NF-kappaB in Adenovirus 5E1-transformed Baby Rat Kidney cells, we now report that the MEK/ERK/p90(rsk1) inhibitor U0126 efficiently blocks TPA-induced IkappaBalpha processing in these cells. However, in U2OS cells, the cytokine-inducible IkappaB kinase complex (IKK) is the essential component of the TPA signal transduction pathway. Activation of the IKK complex in response to TPA is mediated by PKC-alpha, since both the PKC inhibitor GF109203 and a catalytically inactive PKC-alpha mutant inhibit activation of endogenous IKK by TPA, but not by tumor necrosis factor-alpha (TNF-alpha). We conclude that IKK is an integrator of TNF-alpha and TPA signal transduction pathways in U2OS cells.

Identification of the promoter region of chicken anemia virus (CAV) containing a novel enhancer-like element.

The single promoter region in the cloned genome [Noteborn et al., J. Virol. 65 (1991) 3131-3139] of chicken anemia virus (CAV) in chicken T-cells was analysed via CAT assays. A unique region containing four or five near-perfect direct repeats (DR) of 21 bp with one 12-bp insert was proven to be the main transcription-activation element, with enhancer-like characteristics. PCR studies revealed that CAV isolates from across the world all contained this promoter sequence. Electrophoretic mobility-shift assays (EMSA) showed that individual DR units, as well as the 12-bp insert, can bind to nuclear factors of chicken T-cells. Competition assays revealed that the DR units bound to factors other than the 12-bp insert. A synthetic oligodeoxyribonucleotide containing an SP1-box (5'-GGGCGG) could compete with factors binding to the 12-bp insert. Purified human SP1 was shown to have very strong affinity for the 12-bp insert.

Transcription of the chicken anemia virus (CAV) genome and synthesis of its 52-kDa protein.

This paper describes the expression of the chicken anemia virus (CAV) genome, a recently characterized single-stranded circular-DNA virus of a new type [Noteborn et al., J. Virol. 65 (1991) 3131-3139]. The major transcript from the CAV genome is an unspliced mRNA of about 2100 nucleotides (nt). Its transcription start point and poly(A)-addition site are located at nt 354 and 2317 of the CAV sequence, respectively. In vitro translation experiments provide evidence that the major CAV open reading frame encodes a 52-kDa protein by using the fifth AUG as a start codon of the unspliced CAV mRNA.

Cyclin-dependent kinases and pRb: regulators of the proliferation-differentiation switch.

The retinoblastoma susceptibility gene (RB1) is essential for normal embryonic development. Loss of RB1 leads to uncontrolled proliferation of a number of cell types but may also prevent proper terminal differentiation. The growth-suppressive and differentiation-inducing properties of pRb are impaired by cyclin-dependent kinase (cdk)-mediated phosphorylation. Hence, inhibition of cdk activity is probably a prerequisite for terminal differentiation. Indeed, forced cyclin or cdk expression can prevent terminal differentiation in various cell types, probably through inhibition of pRb and, possibly, differentiation-specific transcription factors.

cDNA micro array identification of a gene differentially expressed in adenovirus type 5- versus type 12-transformed cells.

Proteins encoded by non-oncogenic adenovirus type 5 and oncogenic adenovirus type 12 differentially affect expression of a number of cellular genes. We have used cDNA micro array analysis to identify a cellular gene that is expressed in Ad12- but not in Ad5-transformed cells. This cellular gene was found to be the gene encoding follistatin-related protein, a TGF-beta inducible gene. Consistently, a constitutive factor binding to Smad binding elements was found in adenovirus type 12-transformed cells.

Induction of polyploidy in adenovirus E1-transformed cells by the mitotic inhibitor colcemid.

Adenovirus-transformed cells were tested for their ability to synthesize DNA in the presence of cell cycle inhibitory drugs. We show that transformed cells are completely resistant to the mitotic inhibitor colcemid, partly resistant to lovastatin, mimosine, aphidicolin and genistein but not to hydroxyurea or thymidine. When treated with colcemid, AdE1-transformed cells continue to synthesize DNA but do not divide and, therefore, become highly polyploid. This effect is dependent on the presence of both E1A and E1B.