Matsuoka Daisuke, Nanmori Takashi, Sato Ken-ichi, Fukami Yasuo, Kikkawa Ushio, Yasuda Takeshi
Graduate School of Science and Technology, Department of Biological and Environmental Science, Faculty of Agriculture, Kobe University, Rokkodai-cho, Nada-ku, Kobe 657-8501, Japan.
Plant J. 2002 Mar;29(5):637-47. doi: 10.1046/j.0960-7412.2001.01246.x.
The mitogen-activated protein kinase (MAPK) cascade, consisting of MAPK, MAPK kinase (MAPKK) and MAPK kinase kinase (MAPKKK), is the signaling system that relays various external signals, including mitogens and stresses in eukaryotes. MAPKK is activated by phosphorylation in the consensus motif, SXXXS/T, in animals, but the regulation mechanism for the plant MAPKK by phosphorylation, having the putative phosphorylation motif of S/TXXXXXS/T, is not yet fully clarified. Here we constructed a series of mutants of AtMEK1, an Arabidopsis MAPKK, having the sequence T218-X-S220-X-X-X-S224 that fits both of the plant- and animal-type motifs. We show that the two double-mutant proteins replacing Thr-218/Ser-224 and Ser-220/Ser-224 by Glu expressed in Escherichia coli show a constitutive activity to phosphorylate the Thr and Tyr residues of the kinase-negative mutant of an Arabidopsis MAPK, named ATMPK4, in vitro. The mutation analysis of AtMEK1 replacing Thr-218 and Ser-220 to Ala suggested that Thr-218 is autophosphorylated by the enzyme. The wild-type ATMPK4 was also phosphorylated by the active mutants of AtMEK1 and showed a high protein kinase activity toward myelin basic proteins. In contrast, ATMPK3, another Arabidopsis MAPK, was a poor substrate of this plant MAPKK, indicating that AtMEK1 has a substrate specificity preferring ATMPK4 to ATMPK3, at least in vitro. Furthermore, AtMEK1 immunoprecipitated from Arabidopsis seedlings stimulated with wounding, cold, drought, and high salt showed an elevated protein kinase activity toward the kinase-negative ATMPK4, while the amounts of the AtMEK1 protein did not change significantly. These data indicate that the AtMEK1 becomes an active form through phosphorylation and activates its downstream target ATMPK4 in stress response in Arabidopsis.
丝裂原活化蛋白激酶(MAPK)级联反应由MAPK、MAPK激酶(MAPKK)和MAPK激酶激酶(MAPKKK)组成,是一种信号系统,可传递包括有丝分裂原和真核生物应激在内的各种外部信号。在动物中,MAPKK通过共有基序SXXXS/T中的磷酸化被激活,但具有假定磷酸化基序S/TXXXXXS/T的植物MAPKK的磷酸化调控机制尚未完全阐明。在此,我们构建了一系列拟南芥MAPKK AtMEK1的突变体,其序列T218-X-S220-X-X-X-S224同时符合植物型和动物型基序。我们发现,在大肠杆菌中表达的将Thr-218/Ser-224和Ser-220/Ser-224替换为Glu的两种双突变蛋白在体外对拟南芥MAPK激酶阴性突变体(名为ATMPK4)的苏氨酸和酪氨酸残基具有组成型磷酸化活性。将AtMEK1的Thr-218和Ser-220替换为丙氨酸的突变分析表明,Thr-218可被该酶自身磷酸化。野生型ATMPK4也可被AtMEK1的活性突变体磷酸化,并对髓鞘碱性蛋白表现出高蛋白激酶活性。相比之下,另一种拟南芥MAPK ATMPK3是这种植物MAPKK的不良底物,这表明AtMEK1至少在体外具有优先选择ATMPK4而非ATMPK3的底物特异性。此外,从经创伤、寒冷、干旱和高盐刺激的拟南芥幼苗中免疫沉淀的AtMEK1对激酶阴性的ATMPK4表现出升高的蛋白激酶活性,而AtMEK1蛋白的量没有显著变化。这些数据表明,AtMEK1通过磷酸化成为活性形式,并在拟南芥的应激反应中激活其下游靶点ATMPK4。
