Identification of an inducible 85-kDa nuclear protein kinase.

To identify inducible protein kinases localized exclusively in the nucleus, nuclear and cytosolic extracts were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and electroblotted to an Immobilon-P membranes were incubated in phosphorylation buffer containing [gamma-32P]ATP. Autoradiographs of the membranes revealed an 85-kDa 32P-labeled band; the intensity of this band was transiently increased in nuclear but not in cytosolic extracts from interleukin-1 alpha-treated cells. Incorporation of 32P label into a blotted protein band suggested the presence of an interleukin-1 alpha-responsive 85-kDa nuclear protein kinase. Fractionation of nuclear extracts by Mono Q failed to separate the kinase activity from the substrate, indicating that the 85-kDa band identified on the Immobilon-P membrane represents a protein kinase that undergoes autophosphorylation. Phosphoamino acid analysis of the 85-kDa band showed that this enzyme is a serine/threonine kinase. Purified pp90RSK could not be identified by the denaturation-renaturation method, indicating that the 85-kDa kinase identified here is not pp90RSK. This observation, nuclear but not cytoplasmic localization, and the fact that antibodies to known protein kinases kinase failed to recognize it suggest that the enzyme identified here is a novel protein kinase.

Evidence that interleukin-1 and phorbol esters activate NF-kappa B by different pathways: role of protein kinase C.

Nuclear factor kappa B (NF-kappa B) is a ubiquitous transcription factor that affects expression of many genes, including immunoglobulin kappa (kappa), the interleukin-2 receptor alpha chain, and two genes in HIV-1. NF-kappa B can be activated by a number of stimuli, including pharmacological stimulation of protein kinase C by phorbol 12-myristate 13-acetate (PMA) and treatment in vitro with either protein kinase C or protein kinase A. This has lead to the proposal that these kinases are key enzymes in the physiological activation of NF-kappa B as well. We have used a murine B cell line, 70Z/3, and T cell line, EL-4 6.1 C10, to study the activation of NF-kappa B by two physiological activators, interleukin-1 alpha (IL-1) and lipopolysaccharide (LPS). There are four reasons to propose that these agents activate pathways that do not include protein kinase C as a major component in these cell lines. First, the protein kinase C inhibitor 1-(5-isoquinolinesulfonyl)-2-methylpiperazine (H-7) strongly inhibited PMA-induced activation of NF-kappa B in 70Z/3 cells but had no effect on NF-kappa B activated by IL-1 or LPS. Second, depletion of protein kinase C by prolonged growth of 70Z/3 in PMA abrogated the capacity of the cells to activate NF-kappa B in response to further PMA treatment. However, these same cells activated NF-kappa B normally after either IL-1 or LPS treatment. Third, IL-1 effectively activated NF-kappa B in EL-4 6.1 C10 cells, but PMA did not. Fourth, interferon-gamma is a potent activator of protein kinase C in 70Z/3 cells, but is completely inactive in the mobilization of NF-kappa B. These results suggest that the physiological inducers IL-1 and LPS activate NF-kappa B by pathways independent of protein kinase C in both 70Z/3 and EL-4 6.1 C10 cells.

Role of cAMP in interleukin-1-induced kappa light chain gene expression in murine B cell line.

The murine lymphoid cell line 70Z/3 has been extensively used to study the intracellular mechanisms of interleukin-1 (IL-1) action. In these cells IL-1 is known to induce kappa gene expression but the signal transduction pathway has yet to be defined. IL-1-induced kappa expression is associated with stimulation of Na+/H+ exchange and activation of protein kinase C, but these events are not sufficient to trigger kappa expression. Thus, other signals must be present. Because cAMP is a well recognized second messenger, we sought to determine whether cAMP is the signal that triggers IL-1-induced kappa expression. To that end we first measured intracellular levels of cAMP following IL-1 treatment. The results showed that exposure of 70Z/3 cells to IL-1 alpha induced a rapid and a transient increase in cAMP, it peaked at 5 min and was back to base-line level at 20 min. Prostaglandin E2 (PGE2) also increased cAMP with similar kinetics to IL-1 alpha but the increased levels were far greater. IL-1 alpha-induced increase in cAMP proved not be a sufficient signal because an increase in intracellular cAMP by N6,O2'-dibutyryl cAMP (Bt2cAMP) or PGE2 failed to increase surface IgM or to increase kappa mRNA level. Although when used alone they had no effect, Bt2cAMP and PGE2 were found to amplify the IL-1 alpha-induced kappa expression. IL-1 alpha transiently activated NF-kappa B transcription factor. But this effect could not be simulated by Bt2cAMP or PGE2. This observation provides further evidence that cAMP is not a trigger of kappa expression. Although Bt2cAMP or PGE2 when used alone had no effect, they did consistently modify the level of NF-kappa B activity induced by IL-1 alpha. Results of this study show that cAMP is not sufficient to induce NF-kappa B or kappa expression. Therefore, the role of cAMP may not be trigger but rather to modulate the IL-1 alpha-induced kappa expression. Regulation of the response could occur at one or a number of points along the signal pathway. Such a regulatory role is supported by the observation that cAMP modulates the IL-1 alpha-induced NF-kappa B activity.

Properties of interleukin-1 and interferon-gamma receptors in B lymphoid cell line.

We have previously shown that interleukin-1 alpha (IL-1 alpha) and interferon-gamma (IFN-gamma) induce surface IgM expression, stimulate Na+/H+ exchange, and activate protein kinase C in the murine pre-B lymphocyte cell line, 70Z/3. Because the two structurally different lymphokines induce similar effects, in this study we set out to compare the properties of the IL-1 and IFN-gamma surface receptors. In contrast to their similar cellular effects, we found that IL-1 alpha and IFN-gamma receptors have different properties. 70Z/3 have high (100 sites/cell) and low (900 sites/cell) affinity IL-1 receptors with dissociation constants (KD) 6 x 10(-11) and 10(-9) M, respectively. In contrast, IFN-gamma receptors are of one class with a KD of 3 x 10(-10) M and are at a higher number, 8000 sites/cell. After binding to their receptors both IL-1 alpha and IFN-gamma are internalized and intracellularly degraded, but the rate of internalization of IFN-gamma is greater than IL-1 alpha. The effective median concentrations (EC50) of IL-1 alpha- or IFN-gamma-induced surface IgM expression are similar (4-5 x 10(-12) M). However, at this concentration 10-fold more of IFN-gamma than IL-1 alpha molecules are bound per cell. Our studies indicate that structurally different lymphokines can induce similar biological events even though their signaling is mediated by surface receptors whose properties are different.