Interdependent domains controlling the enzymatic activity of mitogen-activated protein kinase kinase 1.

The activation of human mitogen-activated protein kinase kinase 1 (MKK1) is achieved by phosphorylation at Ser218 and Ser222 within a regulatory loop. Partial activation was achieved by replacing these residues with aspartic/glutamic acid. Higher activity was obtained by introducing four acidic residue substitutions in the regulatory loop, indicating that acidic residues in the loop stabilize an active configuration by the introduction of negative charge. Activation of MKK1 is also achieved by deleting residues 44-51, N-terminal to the consensus catalytic core. Although substitution of residues within this segment by alanine does not affect activity, introduction of proline residues elevates kinase activity, indicating that activation results from perturbation of secondary structure within residues 44-51. Pseudosubstrate inhibition, a commonly observed mechanism of kinase regulation, is not operative in this process. Both the acidic substitutions and the N-terminal deletion increase Vmax, V/K(m),ERK2, and V/K(m),ATP, as is also observed following phosphorylation of wild-type MKK1. A synergistic enhancement of these steady-state rate parameters occurs upon combining the mutations, suggesting that conformational changes induced by mutagenesis together mimic those seen upon phosphorylation.

Constitutively active mitogen-activated protein kinase kinase 1 (MAPKK1) and MAPKK2 mediate similar transcriptional and morphological responses.

Both mitogen-activated protein kinase kinase 1 (MAPKK1) and MAPKK2 function downstream of the proto-oncogene product Raf in signaling pathways that affect cell proliferation and differentiation. The isoforms were previously shown to be differentially regulated in two significant ways: (a) MAPKK1, but not MAPKK2, was phosphorylated and inactivated by the cyclin-dependent kinase p34cdc2; and (b) p21 Ras formed a ternary complex with Raf/MAPKK1 but not with Raf/MAPKK2. To further characterize the regulation and function of the two isoforms, we compared their mode of activation by v-Mos and examined the transcriptional and morphological responses that they mediate in cultured mammalian cells. v-Mos enhanced the enzymatic activity of both isoforms to the same extent, by about 600-fold. Constitutively active MAPKK2 mutants were generated by introducing the same deletion and amino acid substitutions that have been shown to activate MAPKK1, suggesting that the conformational changes that lead to their activation are analogous. These mutants potentiated transcription from a promoter containing AP1-responsive elements and induced morphological transformation when expressed in mammalian cells, matching outcomes observed with constitutively active MAPKK1. The specific activity of p42 MAPK in the transformed cells was 3-fold higher than in cells expressing wild-type MAPKK, thereby implicating p42 MAPK as a common effector in vivo, and suggesting that sustained activation of p42 MAPK may represent a critical factor that contributes to the development of the transformed state. Altogether, the results demonstrate that the two isoforms elicit similar responses in vivo despite differences in their regulation.

Determination of v-Mos-catalyzed phosphorylation sites and autophosphorylation sites on MAP kinase kinase by ESI/MS.

MAP kinase kinase (MAPKK), a key component of the MAP kinase cascade, is activated through phosphorylation by several protein kinases, including the oncogene v-Mos and its cellular counterpart, c-Mos. The v-Mos-catalyzed phosphorylation sites on recombinant MAPKK1 were identified by electrospray ionization mass spectrometry as S218 and S222, located within a sequence that aligns with the T loop structure of cAMP-dependent protein kinase; these are the same as the Raf-1 phosphorylation site identified previously [Alessi, D. R., et al. (1994) EMBO J. 13, 1610-1619]. Phosphorylation of these sites was kinetically ordered, with S222 preferred over S218. Intramolecular autophosphorylation of these sites was kinetically ordered, with S222 preferred over S218. Intramolecular autophosphorylation of MAPKK occurred at several residues and was increased upon the stimulation of MAPKK activity by v-Mos. Major autophosphorylation sites were residues S298 and Y300. Minor autophosphorylation sites included T23, S299, S218, and either S24 or S25. Sequence similarities were noted between MAPKK autophosphorylation sites and exogenous phosphorylation sites on MAP kinase. Phosphorylation of either S218 or S222 was sufficient for partial MAPKK activation by Mos, and phosphorylation of S222 alone was sufficient for autophosphorylation at S298 and Y300. Mass spectral analysis was also performed on MAPKK1 purified from rabbit skeletal muscle. The peptide containing S218 and S222 was observed in only a singly phosphorylated form, and the peptide containing S298, S299, and Y300 was observed in multiply phosphorylated forms, suggesting that MAPKK is only partially phosphorylated within the T loop but significantly modified in the autophosphorylation loop under physiological conditions.

Transformation of mammalian cells by constitutively active MAP kinase kinase.

Mitogen-activated protein (MAP) kinase kinase (MAPKK) activates MAP kinase in a signal transduction pathway that mediates cellular responses to growth and differentiation factors. Oncogenes such as ras, src, raf, and mos have been proposed to transform cells by prolonging the activated state of MAPKK and of components downstream in the signaling pathway. To test this hypothesis, constitutively active MAPKK mutants were designed that had basal activities up to 400 times greater than that of the unphosphorylated wild-type kinase. Expression of these mutants in mammalian cells activated AP-1-regulated transcription. The cells formed transformed foci, grew efficiently in soft agar, and were highly tumorigenic in nude mice. These findings indicate that constitutive activation of MAPKK is sufficient to promote cell transformation.