Ana Cuenda

SB 203580 is a specific inhibitor of a MAP kinase homologue which is stimulated by cellular stresses and interleukin-1

A class of pyridinyl imidazoles inhibit the MAP kinase homologue, termed here reactivating kinase (RK) [Lee et al. (1994) Nature 372, 739–746]. We now show that one of these compounds (SB 203580) inhibits RK in vitro (IC50 = 0.6 μM), suppresses the activation of MAPKAP kinase‐2 and prevents the phosphorylation of heat shock protein (HSP) 27 in response to interleukin‐1, cellular stresses and bacterial endotoxin in vivo. These results establish that MAPKAP kinase‐2 is a physiological RK substrate, and that HSP27 is phosphorylated by MAPKAP kinase‐2 in vivo. The specificity of SB 203580 was indicated by its failure to inhibit 12 other protein kinases in vitro, and by its lack of effect on the activation of RK kinase and other MAP kinase cascades in vivo. We suggest that SB 203580 will be useful for identifying other physiological roles and targets of RK and MAPKAP kinase‐2.

Activation of the novel stress-activated protein kinase SAPK4 by cytokines and cellular stresses is mediated by SKK3 (MKK6); comparison of its substrate specificity with that of other SAP kinases.

A cDNA was cloned that encodes human stress‐activated protein kinase‐4 (SAPK4), a novel MAP kinase family member whose amino acid sequence is ∼60% identical to that of the other three SAP kinases which contain a TGY motif in their activation domain. The mRNA encoding SAPK4 was found to be widely distributed in human tissues. When expressed in KB cells, SAPK4 was activated in response to cellular stresses and pro‐inflammatory cytokines, in a manner similar to other SAPKs. SAPK4 was activated in vitro by SKK3 (also called MKK6) or when co‐transfected with SKK3 into COS cells. SKK3 was the only activator of SAPK4 that was induced when KB cells were exposed to a cellular stress or stimulated with interleukin–1. These findings indicate that SKK3 mediates the activation of SAPK4. The substrate specificity of SAPK4 in vitro was similar to that of SAPK3. Both enzymes phosphorylated the transcription factors ATF2, Elk‐1 and SAP‐1 at similar rates, but were far less effective than SAPK2a (also called RK/p38) or SAPK2b (also called p38β) in activating MAPKAP kinase‐2 and MAPKAP kinase‐3. Unlike SAPK1 (also called JNK), SAPK3 and SAPK4 did not phosphorylate the activation domain of c‐Jun. Unlike SAPK2a and SAPK2b, SAPK4 and SAPK3 were not inhibited by the drugs SB 203580 and SB 202190. Our results suggest that cellular functions previously attributed to SAPK1 and/or SAPK2 may be mediated by SAPK3 or SAPK4.

Activation of stress‐activated protein kinase‐3 (SAPK3) by cytokines and cellular stresses is mediated via SAPKK3 (MKK6); comparison of the specificities of SAPK3 and SAPK2 (RK/p38)

Stress‐activated protein kinase‐3 (SAPK3), a recently described MAP kinase family member with a widespread tissue distribution, was transfected into several mammalian cell lines and shown to be activated in response to cellular stresses, interleukin‐1 (IL‐1) and tumour necrosis factor (TNF) in a similar manner to SAPK1 (also termed JNK) and SAPK2 (also termed p38, RK, CSBP and Mxi2). SAPK3 and SAPK2 were activated at similar rates in vitro by SAPKK3 (also termed MKK6), and SAPKK3 was the only activator of SAPK3 that was induced when KB or 293 cells were exposed to cellular stresses or stimulated with IL‐1 or TNF. Co‐transfection with SAPKK3 induced SAPK3 activity and greatly enhanced activation in response to osmotic shock. These experiments indicate that SAPKK3 mediates the activation of SAPK3 in several mammalian cells. SAPK3 and SAPK2 phosphorylated a number of proteins at similar rates, including the transcription factors ATF2, Elk‐1 and SAP1, but SAPK3 was far less effective than SAPK2 in activating MAPKAP kinase‐2 and MAPKAP kinase‐3. Unlike SAPK2, SAPK3 was not inhibited by the drug SB 203580. SAPK3 phosphorylated ATF2 at Thr69, Thr71 and Ser90, the same residues phosphorylated by SAPK1, whereas SAPK2 only phosphorylated Thr69 and Thr71. Our results suggest that cellular functions previously attributed to SAPK1 and/or SAPK2 may be mediated by SAPK3.

Phosphorylation of microtubule-associated protein tau by stress-activated protein kinases.

The paired helical filament, which comprises the major fibrous element of the neurofibrillary lesions of Alzheimers disease, is composed of hyperphosphorylated microtubule‐associated protein tau. Many of the hyperphosphorylated sites in tau are serine/threonine‐prolines. Here we show that the stress‐activated protein (SAP) kinases SAPK1γ (also called JNK1), SAPK2a (also called p38, RK, CSBPs, Mpk2 and Mxi2), SAPK2b (also called p38β), SAPK3 (also called ERK6 and p38γ) and SAPK4 phosphorylate tau at many serine/threonine‐prolines, as assessed by the generation of the epitopes of phosphorylation‐dependent anti‐tau antibodies. Based on initial rates of phosphorylation, tau was found to be a good substrate for SAPK4 and SAPK3, a reasonable substrate for SAPK2b and a relatively poor substrate for SAPK2a and SAPK1γ. Phosphorylation of tau by SAPK3 and SAPK4 resulted in a marked reduction in its ability to promote microtubule assembly. These findings double the number of candidate protein kinases for the hyperphosphorylation of tau in Alzheimers disease and other neurodegenerative disorders.

p38/RK is essential for stress-induced nuclear responses: JNK/SAPKs and c-Jun/ATF-2 phosphorylation are insufficient

The ERK, JNK/SAPK and p38/RK MAP kinase subtypes (reviewed in [1]) are differentially activated in mammalian cells by various stimuli, which elicit induction of immediate-early (IE) genes, such as c-fos and c-jun (reviewed in [1-3]), as well as phosphorylation of histone H3 [4] and HMG-14 [5]. Anisomycin and UV radiation have been suggested to induce c-fos and c-jun transcription via JNK/SAPK-mediated phosphorylation of TCF (ternary complex factor), for c-fos induction [6-8], and c-Jun and/or ATF-2 for c-jun induction [9-11] [12,13]. We report here that anisomycin and ultraviolet radiation (UV) activate MAP kinase kinase-6 (MKK6) [14,15], p38/RK [16] [17,18] and MAPKAP kinase-2 (MAPKAP K-2) [17-19]. By using the p38/RK inhibitor SB 203580 [20,21], we show that activation of p38/RK and/or its downstream effectors are essential for anisomycin- and UV-stimulated c-fos/c-jun induction and histone H3/HMG-14 phosphorylation, whereas JNK/SAPK activation and phosphorylation of c-Jun and ATF-2 are insufficient for these responses.

p38γ regulates the localisation of SAP97 in the cytoskeleton by modulating its interaction with GKAP

Activation of the p38 MAP kinase pathways is crucial for the adaptation of mammalian cells to changes in the osmolarity of the environment. Here we identify SAP97/hDlg, the mammalian homologue of the Drosophila tumour suppressor Dlg, as a physiological substrate for the p38γ MAP kinase (SAPK3/p38γ) isoform. SAP97/hDlg is a scaffold protein that forms multiprotein complexes with a variety of proteins and is targeted to the cytoskeleton by its association with the protein guanylate kinase‐associated protein (GKAP). The SAPK3/p38γ‐catalysed phosphorylation of SAP97/hDlg triggers its dissociation from GKAP and therefore releases it from the cytoskeleton. This is likely to regulate the integrity of intercellular–junctional complexes, and cell shape and volume in response to osmotic stress.

Purification and cDNA cloning of SAPKK3, the major activator of RK/p38 in stress- and cytokine-stimulated monocytes and epithelial cells.

Two chromatographically distinct stress‐activated protein kinase kinases (SAPKKs) have been identified in several mammalian cells, termed SAPKK2 and SAPKK3, which activate the MAP kinase family member RK/p38 but not JNK/SAPK in vitro. Here we demonstrate that SAPKK2 is identical or very closely related to the MAP kinase kinase family member MKK3. However, under our assay conditions, SAPKK3 was the major activator of RK/p38 detected in extracts prepared from stress‐ or interleukin‐1‐stimulated epithelial (KB) cells, from bacterial lipopolysaccharide and tumour necrosis factor alpha‐stimulated THP1 monocytes or from rabbit skeletal muscle. The activated form of SAPKK3 was purified from muscle to near homogeneity, and tryptic peptide sequences were used to clone human and murine cDNAs encoding this enzyme. Human SAPKK3 comprised 334 amino acids and was 78% identical to MKK3. The murine and human SAPKK3 were 97% identical in their amino acid sequences. We also cloned a different murine cDNA that appears to encode a SAPKK3 protein truncated at the N‐terminus. SAPKK3 is identical to the recently cloned MKK6.

Involvement of mitogen-activated protein kinase homologues in the regulation of lipopolysaccharide-mediated induction of cyclo-oxygenase-2 but not nitric oxide synthase in RAW 264.7 macrophages.

In RAW 264.7 macrophages lipopolysaccharide (LPS) stimulated the activation of p42 and p44 MAP kinases and their upstream activator mitogen-activated protein (MAP) kinase kinase (MAPKK), and induced the 69-kDa isoform of cyclo-oxygenase-2 (COX-2) and the 130-kDa isoform of nitric oxide synthase (iNOS). PD 098059, a specific inhibitor of the activation of MAPKK, prevented LPS-mediated activation of MAPKK (IC50 = 3.0 +/- 0.1 microM, n = 3) and p42/44 MAP kinases and substantially reduced the induction of COX-2 by approximately 40%-70%, but was without effect upon the induction of iNOS. In parallel, LPS also stimulated the activation of p38 MAP kinase and the MAPKAP kinase-2, a downstream target of p38 MAP kinase. SB 203580, a specific inhibitor of p38 MAP kinase prevented the activation of p38 MAP kinase (IC50 = 3.3 +/- 1.4 microM, n = 3) and MAPKAP kinase-2 by LPS and reduced the induction of COX-2 by approximately 50-90%, with no significant effect upon iNOS expression. These studies indicate the involvement of both the classical p42/44 MAP kinases and p38 MAP kinase in the regulation of COX-2 but not iNOS induction following exposure to LPS.

Effects of the inhibition of p38/RK MAP kinase on induction of five fos and jun genes by diverse stimuli.

The ERK, JNK/SAPK and p38/RK MAP kinase subtypes are differentially activated by physiological, pharmacological and stress stimuli; all three subtypes are implicated in immediate-early (IE) gene induction by these agents. Here, we have asked whether inhibition of a single MAP kinase subtype under these conditions would generally alter induction of several IE genes in a similar way or whether this would differentially up- and down-regulate particular IE genes, an issue which bears on the question of whether individual MAP kinases are strictly targeted to specific IE genes, or whether they might catalyse phosphorylation events that affect several IE genes in the same way. SB 203580, an inhibitor of p38/RK, has been used to analyse the role of this kinase in the induction of five IE genes (c-fos, fosB, c-jun, junB and junD) under diverse conditions of stimulation. In C3H 10T½ cells, p38/RK and its downstream kinase MAPKAP K-2 are activated by all stimuli used with the exception of TPA. The specificity of SB 203580 as a p38/RK inhibitor in these cells is demonstrated; it does not affect ERKs or JNK/SAPKs but does result in a small increase in the activity of the upstream kinase MKK6, the principal p38/RK activator in these cells. We find that inhibition of p38/RK under these conditions produces general effects on all five IE genes as a group in three ways. First, induction of all five genes in response to okadaic acid or tumour necrosis factor-α (TNF-α) is not significantly altered by SB 203580. Second, in cells stimulated with anisomycin or U.V. radiation, SB 203580 potently inhibits all of the induced IE genes. Finally, SB 203580 enhances induction of all five IE genes in EGF-treated cells; these enhanced mRNA levels are not due to stabilisation of labile mRNA transcripts. The significance of these results to current thinking on the relationship between distinct MAP kinase subtypes and specific IE genes is discussed.

Lithium blocks the PKB and GSK3 dephosphorylation induced by ceramide through protein phosphatase-2A.

The biochemical mechanism of apoptosis induced by ceramide remains still unclear, although it has been reported that dephosphorylation of PKB at Ser-473 may be a key event. In this article, we show that C(2)-ceramide (N-acetyl-sphingosine) induces the dephosphorylation of both protein kinase B (PKB) and glycogen synthase kinase-3 (GSK3) in cerebellar granule cells (CGC). We also show that lithium protects against the apoptosis induced by C(2)-ceramide by blocking the dephosphorylation of both kinases. Since lithium inhibits in vivo the observed protein phosphatase-2A (PP2A) activation induced by ceramide, we hypothesise that the neuroprotective action of lithium may be due to the inhibition of the PP2A activation by apoptotic stimuli.