The c-Fos protein interacts with c-Jun/AP-1 to stimulate transcription of AP-1 responsive genes

Free radicals and the regulation of mammalian cell proliferation

The question of whether free radicals or free radical-related species play a role in the modulation of mammalian cell proliferation is examined. Although a positive role for free radicals as specific components of mitogenic pathways is not apparent it is clear that certain free radical-derived species can have a significant modulatory influence on components of major growth signal transduction mechanisms. Free radical-derived species are also involved in the production of prostaglandins which themselves can modulate cell growth. Free radicals themselves appear to have a down regulatory effect on cell proliferation inasmuch as protection from oxidative stress enhances cell proliferation. On the other hand, in certain cases low levels of active oxygen species can enhance cell proliferation.

Collagenase production by early and late passage cultures of human fibroblasts

Comparison of the proteins secreted by early and late passage cell cultures of human fibroblasts revealed a high level of immunoreactive collagenase (Mr = 55,000 Da and 58,000 Da) in the late passage cell culture conditioned medium. Both molecular weight species reacted with a monoclonal anticollagenase antibody and were apparently glycosylation varaents of the same protein. The question of whether the apparent age-dependent differences in collagenase synthesis reflected changes in protein synthesis or secretion was addressed by assaying immunoreactive collagenase and collagenase mRNA. Immunofluorescence microscopy of cellular collagenase revealed that the percentage of collagenase positive cells ranged from 1 to 6% (early passage) to 35 to 46% (late passage) indicating that the late passage cells had higher basal levels of collagenase synthesis. Later passage cultures also secreted higher levels of immunoprecipitable collagenase into the culture medium and Northern analysis established that the basal level of collagenase mRNA was also 10 times greater in late passage cells. High basal levels of collagenase were also observed in fibroblasts cultured from an in vivo aged donor and from donors with Werner's syndrome. Collagenase production was induced in both early and late passage cell cultures by exposure to fibroblast extracellular matrix, fibroblast conditioned media, polypeptide growth factors, or phorbol esters. The induced levels were always greater in the late passage cell cultures than in the early passage cell cultures.

Oncogenes, protooncogenes, and signal transduction: toward a unified theory?

This paper has reviewed, in a broad sense, the potential involvement of the oncogenes and their progenitors, the protooncogenes, in signal transduction pathways. The membrane-associated oncogene products appear to be connected with the generation and/or regulation of secondary messengers, particularly those associated with Ca2+/phospholipid-dependent activation of the serine/threonine kinase protein kinase C. Activation of transmembrane receptors, either through binding their native ligand or through point mutations that lead to constitutive expression, results in the expression of their intrinsic tyrosine-specific protein kinases. In PDGF-stimulated cells, this results in the increased turnover of phosphatidylinositols and the subsequent release of IP3 (Habenicht et al., 1981; Berridge et al., 1984). This coincides with activation of a PI kinase activity (Kaplan et al., 1987). Likewise, the fms product, which is the receptor for CSF-1, induces a guanine nucleotide-dependent activation of phospholipase C (Jackowski et al., 1986). Receptor functions are potentially regulated through differential binding of ligands (as proposed with PDGF), through interactions with other receptors, and through the "feedback" regulation mediated by protein kinase C. PDGF stimulation leads to modulation of the EGF receptor through protein kinase C (Bowen-Pope et al., 1983; Collins et al., 1983; Davis and Czech, 1985). Similarly, the neu product becomes phosphorylated on tyrosine residues following treatment of cells with EGF, although the neu protein does not bind EGF itself (King et al., 1988; Stern and Kamps, 1988). The tyrosine kinases of the src family are not receptors themselves, although they may mediate specific receptor-generated signals. The clck product is physically and functionally associated with the T-cell receptors CD4 and CD8, and becomes active upon specific stimulation of cells expressing those markers (Veillette et al., 1988a,b). The precise physiological role of the src family products has not been established, but their kinase activity is intrinsic to that function. The v- and c-src products are hyperphosphorylated during mitosis (Chackalaparampil and Shalloway, 1988), which correlates with periods of reduced cell-to-cell adhesion and communication (Warren and Nelson, 1987; Azarnia et al., 1988). Furthermore, pp60c-src is associated with a PI kinase activity when complexed with MTAg of polyoma virus, suggesting a function in stimulating increased turnover of the phosphatidylinositols (Heber and Courtneidge, 1987; Kaplan et al., 1987).(ABSTRACT TRUNCATED AT 400 WORDS)

AP1, a composite transcription factor implicated in abnormal growth control

Growth factors activate cascades of intracellular events, some of which result in altered gene expression. A series of recent discoveries have highlighted the role of the transcription factor AP1 as a mediator of the effects of growth factors, as well as those of oncogenes and the tumour promoter TPA. We discuss the molecular composition of AP1, how its activity is thought to be regulated, and the evidence that AP1 activation is involved in transformation.

The role of the leucine zipper in the fos-jun interaction

Mutagenesis of the fos protein supports the hypothesis that a heptad repeat of leucine residues stabilizes the interaction between the fos and jun proteins. We show that the complex between fos and jun can bind to DNA more tightly than either protein alone and that basic residues adjacent to the leucine repeat of fos contribute to the DNA-binding potential of the complex.

Direct interaction between fos and jun nuclear oncoproteins: role of the 'leucine zipper' domain

Gene expression is modulated by the specific interactions of nuclear proteins with unique regulatory sequences in the genome. Proteins involved in transcriptional regulation seem to be either transcription factors or transcription modulators and their interactions are crucial in determining whether the expression of a specific gene is activated or repressed. Recently, the product of the proto-oncogene jun has been identified as the transcription factor AP-1, whereas nuclear oncoproteins fos and myc have been implicated in transcriptional transregulation of several promoters. Furthermore, the products of the fos and jun proto-oncogenes are associated in some transcription complexes. Although the nature of the association is unclear, the two proteins co-immunoprecipitate with fos antibodies in nuclear extracts. Here, we report studies that demonstrate that the fos protein directly modulates jun function by means of a heterodimer of fos and jun proteins. The fos 'leucine zipper' domain is necessary for the DNA binding of the heterodimer; a distinct domain, localized in the C-terminal region of the fos protein, is responsible for transcriptional regulation.

Morphine activation of c-fos expression in rat brain

The post-receptor mechanism of opiate action has been studied by examining the activation by morphine of the proto-oncogene c-fos and its encoded nucleoprotein pp55c-fos (FOS) in rat caudate-putamen, which is rich in the mu-type opiate receptor. Following an acute morphine treatment, c-fos mRNA levels in rat caudate-putamen were increased to maximum (420% of control level) at 45 minutes and returned to control levels at 90 minutes. This induction was completely abolished by naloxone, a morphine antagonist. Fos protein, detected by immunocytochemistry, was also increased 3 hours after morphine injection, in the caudate-putamen, but not in the olfactory tubercle, which does not have the mu-type opiate receptor. Upon activation of opiate receptors by morphine, the c-fos gene is activated and Fos protein may act as a signal transducer uniquely involved in the mechanism of opiate addiction at the level of gene regulation.

Growth factors regulate transin gene expression by c-fos-dependent and c-fos-independent pathways

The rapid induction of the proto-oncogene c-fos by growth factors and other bioactive agents, and the recent evidence that the c-fos protein (Fos) is associated with transcriptional complexes, suggests that Fos may represent an integral part of an intracellular messenger pathway that triggers changes in gene expression and ultimately phenotypic alterations. This report examines the role of c-fos in growth factor stimulation of transin, a matrix-degrading secreted metalloproteinase. Platelet-derived growth factor (PDGF) stimulation of transin RNA was blocked by a selective reduction in Fos synthesis with antisense c-fos mRNA, whereas epidermal growth factor (EGF) stimulation of transin occurred despite an equivalent inhibition of Fos levels. The stimulatory effect of both PDGF and EGF on transin transcription involved factors recognizing the sequence TGAGTCA, which is found in the transin promoter and is reported to be a binding site for the transcriptional factor Jun/AP-1 and for associated Fos and Fos-related complexes. Thus both Fos-dependent and Fos-independent pathways exist for growth factor regulation of gene expression, and both effects may be mediated through the same cis-acting transcription element.

The jun proto-oncogene is positively autoregulated by its product, Jun/AP-1

Binding of the human transcription factor Jun/AP-1 to a conserved 8 bp nucleotide sequence (TRE) is responsible for increased transcription of different cellular genes in response to tumor promoters, such as TPA, and serum factors. Enhanced Jun/AP-1 activity in TPA-stimulated cells is regulated by two different mechanisms: a posttranslational event acting on pre-existing Jun/AP-1 molecules, and transcriptional activation of jun gene expression leading to an increase in the total amount of Jun/AP-1. Induction of jun transcription in response to TPA is mediated by binding of Jun/AP-1 to a high-affinity AP-1 binding site in the jun promoter region. Site-specific mutagenesis of this binding site prevents TPA induction and trans-activation by Jun/AP-1. These results clearly demonstrate that jun transcription is directly stimulated by its own gene product. This positive regulatory loop is likely to be responsible for prolonging the transient signals generated by activation of protein kinase C.

DNA binding activities of three murine Jun proteins: stimulation by Fos

Three members of the Jun/AP-1 family have been identified in mouse cDNA libraries: c-Jun, Jun-B, and Jun-D. We have compared the DNA binding properties of the Jun proteins by using in vitro translation products in gel retardation assays. Each protein was able to bind to the consensus AP-1 site (TGACTCA) and, with lower affinity, to related sequences, including the cyclic AMP response element TGACGTCA. The relative binding to the oligonucleotides tested was similar for the different proteins. The Jun proteins formed homodimers and heterodimers with other members of the family, and they were bound to the AP-1 site as dimers. When Fos translation product was present, DNA binding by Jun increased markedly, and the DNA complex contained Fos. The C-terminal homology region of Jun was sufficient for DNA binding, dimer formation, and interaction with Fos. Our general conclusion is that c-Jun, Jun-B, and Jun-D are similar in their DNA binding properties and in their interaction with Fos. If there are functional differences between them, they are likely to involve other activities of the Jun proteins.

c-Jun dimerizes with itself and with c-Fos, forming complexes of different DNA binding affinities

The c-Jun and c-fos proto-oncogenes encode proteins that form a complex which regulates transcription from promoters containing AP-1 activation elements. c-Jun has specific DNA binding activity, while c-Fos has homology to the putative DNA binding domain of c-Jun. Following in vitro translation, c-Jun binds as a homodimer to the AP-1 DNA site, while c-Fos fails to dimerize and displays no apparent affinity for the AP-1 element. Cotranslated c-Jun and c-Fos proteins bind 25 times more efficiently to the AP-1 DNA site as a heterodimer than does the c-Jun homodimer. These experiments suggest that in growth factor-stimulated cells c-Jun binds DNA as a dimer with c-Fos as its natural partner. However, overexpression of c-Jun protein in the absence of c-Fos may result in formation of aberrant homodimeric transcription complexes, which could abrogate the normal mechanisms controlling gene expression.

Calcium as a modulator of the immediate-early gene cascade in neurons

Increases in intraneuronal free calcium result in the rapid, transient, induction of the fos and jun proto-oncogenes. In PC12 cells, induction may be elicited either by membrane depolarization or by direct activation of voltage-dependent calcium channels with BAY K 8644 both of which provoke an influx of calcium. The calmodulin pathway appears to link the elevated intracellular calcium to gene induction. In the brain, c-fos and c-jun may be induced by elevated neuronal activity such as occurs during pentylenetetrazole (PTZ) seizures. The N-methyl-D-aspartate (NMDA) form of the glutamate receptor, which can directly gate calcium, plays a role in the induction of c-fos expression in PTZ seizures. In addition, NMDA can directly stimulate c-fos in the brain. Fos and Jun form a noncovalent nucleoprotein complex that binds to the consensus recognition sequence of the AP-1 transcription factor. Thus in a larger picture we envisage Fos and Jun as members of a concerted stimulus-transcription coupling pathway that links alterations in external stimuli to long term adaptive responses. In this context Fos, Jun and the other immediate-early genes should be viewed as third messengers which are regulated by second messengers such as intracellular calcium.

Converting a eukaryotic transcriptional inhibitor into an activator

GAL80, an inhibitor of the yeast transcriptional activator GAL4, is converted into an activator by inserting an acidic activating sequence into it. This hybrid activator does not bind to DNA directly, but is brought to DNA by interacting with a derivative of GAL4 that interacts with both DNA and GAL80.

A family of immunologically related transcription factors that includes multiple forms of ATF and AP-1

ATF is a cellular transcription factor involved in the regulation of multiple adenovirus E1A- and cellular cAMP-inducible promoters. Using DNA affinity chromatography, we have purified ATF and found that a series of polypeptides copurify in a sequence-specific manner. We demonstrate that these polypeptides represent a family of proteins that are related by DNA-binding specificity and by immunological cross-reactivity. This family includes the transcription factor AP-1, whose recognition sequence, GTGAGTCAA, differs from the ATF consensus, GTGACGTCAA, by the absence of a cytosine residue. Our results further indicate that there are multiple forms of both ATF and AP-1. The immunological cross-reactivity and related DNA-binding specificities suggest that ATF and AP-1 contain similar amino acid sequences and may have originated from a common gene.