Judy L. Meinkoth

Signal transduction through the cAMP-dependent protein kinase

Temporal cellular events responsible for hormonal activation of responses mediated by the cAMP-dependent protein kinase (PKA) have been studied in living cells. By selectively perturbing molecular function of Gs, the catalytic subunit of PKA (C), or the nuclear factor CREB, in cells through microinjection of inhibitory agents specific for these molecules or activated forms of these molecules, we have obtained evidence for a requirement for the function of each of these molecules in the hormonal stimulation of cAMP-regulated genes. Moreover, by introducing fluorescently labeled PKA subunits into these cells as molecular tracers, or by immunofluorescence of C subunit, we have observed biological translocation of C subunit from the cytoplasm to the nucleus during transcriptional activation and a quenching of this by the inhibitor molecule, PKI. The implications of these cellular and molecular events in the signal transduction of hormonal responses are discussed.

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

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.

Inhibition of thyrotropin-stimulated DNA synthesis by microinjection of inhibitors of cellular Ras and cyclic AMP-dependent protein kinase.

Microinjection of a dominant interfering mutant of Ras (N17 Ras) caused a significant reduction in thyrotropin (thyroid-stimulating hormone [TSH])-stimulated DNA synthesis in rat thyroid cells. A similar reduction was observed following injection of the heat-stable protein kinase inhibitor of the cyclic AMP-dependent protein kinase. Coinjection of both inhibitors almost completely abolished TSH-induced DNA synthesis. In contrast to TSH, overexpression of cellular Ras protein did not stimulate the expression of a cyclic AMP response element-regulated reporter gene. Similarly, injection of N17 Ras had no effect on TSH-stimulated reporter gene expression. Moreover, overexpression of cellular Ras protein stimulated similar levels of DNA synthesis in the presence or absence of the heat-stable protein kinase inhibitor. Together, these results suggest that in Wistar rat thyroid cells, a full mitogenic response to TSH requires both Ras and cyclic APK-dependent protein kinase.

A refractory phase in cyclic AMP-responsive transcription requires down regulation of protein kinase A.

Cyclic AMP (cAMP) stimulates the expression of numerous genes through the protein kinase A (PK-A)-mediated phosphorylation of the nuclear factor CREB at Ser-133 (G. A. Gonzalez and M. R. Montminy, Cell 59:675-680, 1989). Like other signal transduction pathways, cAMP induces gene expression with burst-attenuation kinetics; cAMP-dependent transcription and CREB phosphorylation peak within 30 min and decline steadily over the next 4 to 6 h via the protein phosphatase 1-mediated dephosphorylation of CREB (M. Hagiwara, A. Alberts, P. Brindle, J. Meinkoth, J. Feramisco, T. Deng, M. Karin, S. Shenolikar, and M. Montminy, Cell 70:105-113, 1992). Here we characterize a third phase in cAMP-responsive transcription--a refractory period during which hormone-treated cells become transcriptionally unresponsive to subsequent stimulation by cAMP. This refractory period begins 6 to 8 h after stimulation and lasts 3 to 5 days after the removal of hormone. In contrast to the earlier attenuation phase, transcription of cAMP-responsive genes during the refractory period is not restored by inhibitors of protein phosphatase 1 activity. Rather, the establishment and maintenance of this phase rely on a marked reduction in PK-A catalytic subunit expression at the translational level. As overexpression of C-subunit protein can reactive transcription of cAMP-responsive genes during the refractory period, our results suggest that hormone-responsive cells may stimulate, attenuate, and then silence signal-dependent genes through distinct regulatory mechanisms.

Thyrotropin-Induced Mitogenesis Is Ras Dependent but Appears To Bypass the Raf-Dependent Cytoplasmic Kinase Cascade

Cellular growth control requires the coordination and integration of multiple signaling pathways which are likely to be activated concomitantly. Mitogenic signaling initiated by thyrotropin (TSH) in thyroid cells seems to require two distinct signaling pathways, a cyclic AMP (cAMP)-dependent signaling pathway and a Ras-dependent pathway. This is a paradox, since activated cAMP-dependent protein kinase disrupts Ras-dependent signaling induced by growth factors such as epidermal growth factor and platelet-derived growth factor. This inhibition may occur by preventing Raf-1 protein kinase from binding to Ras, an event thought to be necessary for the activation of Raf-1 and the subsequent activation of the mitogen-activated protein (MAP)/extracellular signal-regulated kinase (ERK) kinases (MEKs) and MAP kinase (MAPK)/ERKs. Here we report that serum-stimulated hyperphosphorylation of Raf-1 was inhibited by TSH treatment of Wistar rat thyroid cells, indicating that in this cell line, as in other cell types, increases in intracellular cAMP levels inhibit activation of downstream kinases targeted by Ras. Ras-stimulated expression of genes containing AP-1 promoter elements was similarly inhibited by TSH. On the other hand, stimulation of thyroid cells with TSH resulted in stimulation of DNA synthesis which was Ras dependent but both Raf-1 and MEK independent. We also show that Ras-stimulated DNA synthesis required the use of this kinase cascade in untreated quiescent cells but not in TSH-treated cells. These data suggest that in TSH-treated thyroid cells, Ras might be able to signal through effectors other than the well-studied cytoplasmic kinase cascade.

Induction of a cyclic AMP-responsive gene in living cells requires the nuclear factor CREB.

We constructed cell lines containing various enhancer elements cloned upstream from a marker gene. By microinjection of specific antibodies directed against transcriptional activator proteins into these cell lines, we have developed a functional assay for factors which regulate the activity of target promoters. Here we show that microinjection of a highly specific antibody to the cyclic AMP enhancer element-binding (CREB) protein diminishes gene expression in response to cyclic AMP in living fibroblasts.

Semliki forest virus persistence in mouse L929 cells.

Abstract We present a characterization of the establishment and maintenance of a persistent infection of mouse L929 cells using the alphavirus Semlike Forest virus (SFV). Without interferon pretreatment of the L cells, a persistent infection could only be established using an inoculum rich in defective-interfering (DI) particles. One such persistently infected culture (carrier culture) now over 1 year old, is characterized by cells (i) which are usually morphologically identical to uninfected cells, (ii) which release variable titers of infectious virus, (iii) which periodically enter a state of crisis during which many of the cells perish, and (iv) which can be cured of virus by treatment with viral antiserum. After the first crisis, DI particles could not be detected at any time in the carrier culture. Only a small proportion (0.1–4.5%) of the persistently infected cells released infectious virus and only 1–20% were positive for viral structural antigen. The persistently infected cells were resistant to superinfection by both homologous and heterologous virus. Interferon was present in variable quantities in the fluid from the carrier culture. Indeed a similar persistent infection could readily be established by pretreatment of uninfected cells with 100 units/ml of mouse interferon. In this case DI particles were not required in the inoculum. Using oligonucleotide fingerprinting we demonstrate that viral genomic mutations occur during persistence and that many of these mutations occur in genes coding for the virus structural proteins. On the basis of these observations we present a model for SFV persistence in mouse L929 cells.

Conjugated bile acid uptake by Xenopus laevis oocytes induced by microinjection with ileal Poly A+ mRNA.

Apical membranes of ileal enterocytes contain the major Na+/bile acid cotransporter activity in mammals. Microinjection of guinea pig ileal mucosal Poly A+ mRNA (25 ng) into Xenopus oocytes resulted in 22,23-3H-cholyltaurine uptake at day 3 after injection (453 fmol/oocyte-hr), while control viral mRNA (25 ng) gave an uptake rate of 133 fmol/oocyte-hr. The transport rate increased in direct relationship to the concentration of injected mRNA, cholyltaurine, or Na+ in the incubation media. Uptake of cholyltaurine using rabbit ileal mucosal Poly A+ mRNA was 3891 fmole/oocyte-hr compared to rabbit jejunal-mucosa Poly A+ mRNA (control) injections inducing 728 fmol/oocyte-hr. Such expression of the ileal Na+/bile acid cotransporter may facilitate cloning of this key mammalian gene.