Showing papers by "Michael Karin published in 1993"

Identification of an oncoprotein- and UV-responsive protein kinase that binds and potentiates the c-Jun activation domain.

Abstract: The activity of c-Jun is regulated by phosphorylation. Various stimuli including transforming oncogenes and UV light, induce phosphorylation of serines 63 and 73 in the amino-terminal activation domain of c-Jun and thereby potentiate its trans-activation function. We identified a serine/threonine kinase whose activity is stimulated by the same signals that stimulate the amino-terminal phosphorylation of c-Jun. This novel c-Jun amino-terminal kinase (JNK), whose major form is 46 kD, binds to a specific region within the c-Jun trans-activation domain and phosphorylates serines 63 and 73. Phosphorylation results in dissociation of the c-Jun-JNK complex. Mutations that disrupt the kinase-binding site attenuate the response of c-Jun to Ha-Ras and UV. Therefore the binding of JNK to c-Jun is of regulatory importance and suggests a mechanism through which protein kinase cascades can specifically modulate the activity of distinct nuclear targets.

NF-kappa B activation by ultraviolet light not dependent on a nuclear signal

Abstract: Exposure of mammalian cells to radiation triggers the ultraviolet (UV) response, which includes activation of activator protein-1 (AP-1) and nuclear factor kappa B (NF-kappa B). This was postulated to occur by induction of a nuclear signaling cascade by damaged DNA. Recently, induction of AP-1 by UV was shown to be mediated by a pathway involving Src tyrosine kinases and the Ha-Ras small guanosine triphosphate-binding protein, proteins located at the plasma membrane. It is demonstrated here that the same pathway mediates induction of NF-kappa B by UV. Because inactive NF-kappa B is stored in the cytosol, analysis of its activation directly tests the involvement of a nuclear-initiated signaling cascade. Enucleated cells are fully responsive to UV both in NF-kappa B induction and in activation of another key signaling event. Therefore, the UV response does not require a signal generated in the nucleus and is likely to be initiated at or near the plasma membrane.

Transactivation by NF-IL6/LAP is enhanced by phosphorylation of its activation domain

Abstract: One of the members of the bZIP family of transcriptional activators is NF-IL6/LAP (IL-6 DBP, C/EBP beta, CRP2). NF-IL6/LAP protein is highly expressed in liver nuclei, where it has been implicated as a master regulator of the acute-phase response, induced by interleukin-6 (IL-6) and other inflammatory mediators. Also, NF-IL6/LAP is involved in the activation of the IL-6 promoter in response to IL-1 and bacterial lipopolysaccharide. The control of NF-IL6/LAP expression and activity is complex and poorly understood. Under some conditions the NF-IL6/LAP gene is transcriptionally activated by IL-1 and lipopolysaccharide, whereas in other instances, its binding to cognate DNA sequences is enhanced by cytokines. Additionally, the ability of constitutively expressed NF-IL6/LAP to activate transcription is strongly augmented by IL-6, through an unknown signalling pathway. We now show that stimulation of the protein kinase C pathway increases the phosphorylation of Ser 105 within the activation domain of NF-IL6/LAP, and enhances its transcriptional efficacy.

JunB differs from c-Jun in its DNA-binding and dimerization domains, and represses c-Jun by formation of inactive heterodimers.

Abstract: JunB differs considerably from c-Jun in its ability to activate AP-1-responsive genes and induce oncogenic transformation. We demonstrate that the decreased ability of JunB to activate gene expression is the result of a small number of amino acid changes between its DNA-binding and dimerization motifs and the corresponding regions of c-Jun. These changes lead to a 10-fold decrease in the DNA-binding activity of JunB. JunB can be converted into a c-Jun-like activator by substituting four amino acids in its DNA-binding and dimerization motifs with the corresponding c-Jun sequences. JunB can also attenuate trans-activation by c-Jun, an activity mediated by its leucine zipper. This ability depends on two glycine residues that decrease the stability of the JunB leucine zipper, resulting in decreased homodimerization and increased heterodimerization. These results illustrate how small changes in primary structure, including chemically conservative changes, can result in functional divergence of two highly related transcriptional regulators.

p105 and p98 precursor proteins play an active role in NF-kappa B-mediated signal transduction.

Abstract: The Rel/NF-kappa B family of transcription factors is composed of two distinct subgroups, proteins that undergo proteolytic processing and contain SWI6/ankyrin repeats in their carboxyl termini (p105, p98), and those without such repeats that do not require processing (p65, c-Rel, RelB, and Dorsal). We demonstrate that the p105 and p98 precursors share functional properties with the I kappa B proteins, which also contain SWI6/ankyrin repeats. Both p105 and p98 were found to form stable complexes with other Rel/NF-kappa B family members, including p65 and c-Rel. Association with the precursors is sufficient for cytoplasmic retention of either p65 or c-Rel, both of which are otherwise nuclear. These complexes undergo stimulus-responsive processing to produce active p50/c-Rel and p55/c-Rel complexes. These observations suggest a second pathway leading to NF-kappa B induction, in which processing of the precursors rather than phosphorylation of I kappa B plays a major role.

Transcriptional Control of GH Expression and Anterior Pituitary Development

Abstract: I. Introduction CASCADES of interacting regulatory genes controlling developmental pathways have been defined in organisms such as Drosophila (1–9) and the nematode Caenorhabditis elegans (10–12). The developmental regulators include transcription factors, kinases, phosphatases, growth factors,receptors, and cell-adhesion molecules. In Drosophila, products of maternally expressed genes control expression of zygotic segmentation genes, the products of which regulate homeotic gene expression; regulation is also exerted between genes of the same class. As a result, the embryo is divided into a meshwork of metameric units, each expressing a unique combination of homeotic genes. These genes contain a conserved homeobox, encoding a 60-amino acid homeodomain which functions in DNA binding. By acting as transcription factors, the homeodomain proteins orchestrate activation of a unique combination of target genes which makes the cells enter a specific morphogenetic pathway. The molecular mechanisms underlying regu...

GHF-1-promoter-targeted immortalization of a somatotropic progenitor cell results in dwarfism in transgenic mice.

Abstract: During pituitary development, the homeo domain protein GHF-1 is required for generation of somatotropes and lactotropes and for growth hormone (GH) and prolactin (PRL) gene expression. GHF-1 mRNA is detectable several days before the emergence of GH- or PRL-expressing cells, suggesting the existence of a somatotropic progenitor cell in which GHF-1 transcription is first activated. We have immortalized this cell type by using the GHF-1 regulatory region to target SV40 T-antigen (Tag) tumorigenesis in transgenic mice. The GHF-Tag transgene caused developmental entrapment of somatotropic progenitor cells that express GHF-1 but not GH or PRL, resulting in dwarfism. Immortalized cell lines derived from a transgenic pituitary tumor maintain the characteristics of the somato/lactotropic progenitor in that they express GHF-1 mRNA and protein yet fail to activate GH or PRL transcription. Using these cells, we identified an enhancer that activates GHF-1 transcription at this early stage of development yet is inactive in cells representing later developmental stages of the somatotropic lineage or in other cell types. These experiments not only demonstrate the potential for immortalization of developmental progenitor cells using the regulatory regions from cell type-specific transcription factor genes but illustrate the power of such model systems in the study of developmental control.

A conserved C-terminal sequence that is deleted in v-ErbA is essential for the biological activities of c-ErbA (the thyroid hormone receptor).

Abstract: The thyroid hormone (T3) receptor type alpha, the c-ErbA alpha proto-oncoprotein, stimulates transcription of T3-dependent promoters, interferes with AP-1 activity, and induces erythroid differentiation in a ligand-dependent manner. The v-ErbA oncoprotein does not bind hormone and has lost all of these activities. Using c-ErbA/v-ErbA chimeras, we found that a deletion of 9 amino acids, conserved among many members of the nuclear receptor superfamily, which are located at the extreme carboxy terminus of c-ErbA alpha is responsible for loss of both transactivation and transcriptional interference activities. Single, double, and triple amino acid substitutions within this region completely abolished T3-dependent transcriptional activation, interference with AP-1 activity, and decreased T3 binding by c-ErbA alpha. However, the lower T3 binding by these mutants does not fully account for the loss of transactivation and transcriptional interference, since a c-ErbA/v-ErbA chimera which was similarly reduced in T3 binding activity has retained both of these functions. Deletion of homologous residues in the retinoic acid receptor alpha (RAR alpha) resulted in a similar loss of transactivation and transcriptional interference activities. The ability of c-ErbA alpha to induce differentiation of transformed erythroblasts is also impaired by all of the mutations introduced into the conserved carboxy-terminal sequence. We conclude that this 9-amino-acid conserved region is essential for normal biological function of c-ErbA alpha and RAR alpha and possibly other T3 and RA receptors.

Protein phosphatase 2A potentiates activity of promoters containing AP-1-binding elements.

Abstract: The involvement of serine/threonine protein phosphatases in signaling pathways which modulate the activity of the transcription factor AP-1 was examined. Purified protein phosphatase types 1 (PP1) and 2A (PP2A) were microinjected into cell lines containing stably transfected lacZ marker genes under the control of an enhancer recognized by AP-1. Microinjection of PP2A potentiated serum-stimulated beta-galactosidase expression from the AP-1-regulated promoter. Similarly, transient expression of the PP2A catalytic subunit with c-Jun resulted in a synergistic transactivation of an AP-1-regulated reporter gene. PP2A, but not PP1, potentiated serum-induced c-Jun expression, which has been previously shown to be autoregulated by AP-1 itself. Consistent with these results, PP2A dephosphorylated c-Jun on negative regulatory sites in vitro, suggesting one possible direct mechanism for the effects of PP2A on AP-1 activity. Microinjection of PP2A had no effect on cyclic AMP (cAMP)-induced expression of a reporter gene containing a cAMP-regulated promoter, while PP1 injection abolished cAMP-induced gene expression. Taken together, these results suggest a specific role for PP2A in signal transduction pathways that regulate AP-1 activity and c-Jun expression.

Activation of activating protein 1 during hepatic acute phase response

Abstract: During an acute phase response following inflammatory stimuli, specific changes occur in the synthesis and secretion of many hepatic proteins. Because the expression of differentiated function requires the coordinated regulation of many genes, we investigated the activity of general and tissue-specific transcription factors using a rat liver model of the acute phase response induced by Freund9s adjuvant. Nuclear extracts and RNAs were prepared throughout a 48-h posttreatment period. Mobility shift assays revealed increased binding activity by nuclear factor-kappa B, interleukin-6 (IL-6) responsive element binding protein, and activating protein 1 (AP-1). Two AP-1 complexes were induced during the acute phase response, and correlation between their presence and transcription activity was demonstrated by transfection studies. Elevated binding activity of AP-1 also correlated with elevated levels of c-jun, junD, junB, and c-fos mRNAs. Western blots showed elevated hepatic levels of c-Jun but not c-Fos proteins during the acute phase response. In addition, IL-6, tumor necrosis factor-alpha, and IL-1 beta, cytokine regulators of the acute phase response, stimulated expression of an AP-1 responsive reporter gene introduced by DNA-mediated transfection into adult rat hepatocytes in primary culture. These findings demonstrate the complexity of AP-1 hepatic transcription factor responses to humoral regulators with direct hepatocellular effects.

Various modes of gene regulation by nuclear receptors for steroid and thyroid hormones.

Abstract: AP-1 is a transcriptional activator composed of homo- and heterodimers of Jun and Fos proteins. It is involved in activation of genes, such as collagenase, stromelysin, IL-2 and TGFβ1, by tumour promoters, growth factors and cytokines. AP-1 activity is also elevated in response to transforming oncogenes and is required for cell proliferation. AP-1 activity is subject to complex regulation both transcriptionally and post-transcriptionally. Transcriptional control ofjun andfos gene expression determines the amount and composition of the AP-1 complex. Thejun andfos genes are regulated both positively and negatively and are highly inducible in response to extracellular stimuli. Post translational control is also important. Both cJun and cFos are subject to regulated phosphorylation. In the case of cJun, phosphorylation of sites near the DNA-binding domain inhibits DNA-binding, while dephosphorylation reverses this inhibition. Phosphorylation of cJun on sites within the N-terminal activation domain increases its ability to activate transcription. The protein kinase phosphorylating these sites is stimulated by cytokines and growth factors. Another mechanism modulating AP-1 activity is transcriptional interference by members of the nuclear receptor family and is relevant for the pathophysiology of rheumatoid arthritis (RA). In RA, chronic inflammation leads to increased AP-1 activity in T cells, macrophages and synoviocytes as a response to secretion of cytokines such as IL-1 and TNFα. While the IL-2 gene plays a major role in T cell activation, another AP-1 target gene encodes an enzyme, collagenase, responsible for destruction of bone and tendon. Glucocorticoids and retinoids are capable of repressing expression of both genes as well as other AP-1 target genes. We found that the glucocorticoid and retinoic acid receptors interact with cJun and cFos to inhibit their ability to activate AP-1 target genes.

Promoter Elements and Transcriptional Regulation of the Acetylcholinesterase Gene

Abstract: The 5′ region of the acetylcholinesterase gene from the electric ray Torpedo californica has been cloned and its cap site identified. The 5′ untranslated region is divided into two exons w...