14-304 Sigma-AldrichMKK6/SKK3 Protein, inactive, 50 µg

A cDNA was cloned that encodes human stress-activated protein kinase-4 (SAPK4), a novel MAP kinase family member whose amino acid sequence is approximately 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 p38beta) 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.

The identities of the upstream activators of the mitogen-activated protein (MAP) kinase homologues termed stress-activated-protein (SAP) kinase-1 (also known as JNK or SAPK) and SAP kinase-2 (also known as p38, RK and CSBP) were investigated in rat PC12 cells and human KB cells after exposure to cellular stresses and cytokines. In PC12 cells, the same two upstream activators, SAP kinase kinase-1 (SAPKK-1) and SAPKK-2 were activated after exposure to osmotic shock, ultraviolet irradiation or the protein synthesis inhibitor anisomycin, and more weakly in response to sodium arsenite. SAPKK-1 was capable of activating both SAP kinase-1 and SAP kinase-2 and was similar, if not identical, to the previously described MAP kinase kinase homologue MKK4, as judged by immunological criteria and by its ability to be activated by MEK kinase in vitro. In contrast, SAPKK-2 activated SAP kinase-2, but not SAP kinase-1 in vitro. In KB cells, five distinct upstream activators of SAP kinase-1 and SAP kinase-2 were induced, namely SAPKK-1, SAPKK-2, SAPKK-3, SAPKK-4 and SAPKK-5, whose appearance depended on the nature of the stimulus. SAPKK-3, which was strongly induced by every stimulus tested (osmotic shock, ultraviolet irradiation, anisomycin or IL-1), accounted for about 95% of the SAP kinase-2 activator activity in these cells, did not activate SAP kinase-1 and eluted from Mono S at a lower salt concentration than SAPKK-2. SAPKK-4 and SAPKK-5 were also eluted from Mono S at higher NaC1 concentrations than SAPKK-3 and these enzymes activated SAP kinase-1 but not SAP kinase-2. SAPKK-4 was the only SAP kinase-1 activator induced by interleukin-1 or ultraviolet irradiation, while two SAP kinase-1 activators, SAPKK-1 and SAPKK-5, were induced by osmotic shock or anisomycin. SAPKK-2, SAPKK-3, SAPKK-4 and SAPKK-5, were not activated by MEK kinase in vitro, were separable from the major activator(s) of p42 MAP kinase, and were not recognised by anti-MKK4 antibodies. At least two of these enzymes are likely to be novel MAP kinase kinase homologues. Our results demonstrate unexpected complexity in the upstream regulation of stress and cytokine-stimulated kinase cascades and indicate that the selection of the appropriate SAPKK varies with both the stimulus and the cell type.