The Rho subfamily of GTPases is involved in control of cell morphology in mammals and yeast. The mammalian Rac and Cdc42 proteins control formation of lamellipodia and filopodia, respectively. These proteins also activate MAP kinase (MAPK) cascades that regulate gene expression. Constitutively activated forms of Rac and Cdc42Hs are efficient activators of a cascade leading to JNK and p38/Mpk2 activation. RhoA did not exhibit this activity, and none of the proteins activated the ERK subgroup of MAPKs. JNK, but not ERK, activation was also observed in response to Dbl, an oncoprotein that acts as a nucleotide exchange factor for Cdc42Hs. Results with dominant interfering alleles place Rac1 as an intermediate between Ha-Ras and MEKK in the signaling cascade leading from growth factor receptors and v-Src to JNK activation. JNK and p38 activation are likely to contribute to the biological effects of Rac, Cdc42Hs, and Dbl on cell growth and proliferation.
One Ras-dependent protein kinase cascade leading from growth factor receptors to the ERK (extracellular signal-regulated kinases) subgroup of mitogen-activated protein kinases (MAPKs) is dependent on the protein kinase Raf-1, which activates the MEK (MAPK or ERK kinase) dual specificity kinases. A second protein kinase cascade leading to activation of the Jun kinases (JNKs) is dependent on MEKK (MEK kinase). A dual-specificity kinase that activates JNK, named JNKK, was identified that functions between MEKK and JNK. JNKK activated the JNKs but did not activate the ERKs and was unresponsive to Raf-1 in transfected HeLa cells. JNKK also activated another MAPK, p38 (Mpk2; the mammalian homolog of HOG1 from yeast), whose activity is regulated similarly to that of the JNKs.
Growth factors induce c‐fos transcription by stimulating phosphorylation of transcription factor TCF/Elk‐1, which binds to the serum response element (SRE). Under such conditions Elk‐1 could be phosphorylated by the mitogen‐activated protein kinases (MAPKs) ERK1 and ERK2. However, c‐fos transcription and SRE activity are also induced by stimuli, such as UV irradiation and activation of the protein kinase MEKK1, that cause only an insignificant increase in ERK1/2 activity. However, both of these stimuli strongly activate two other MAPKs, JNK1 and JNK2, and stimulate Elk‐1 transcriptional activity and phosphorylation. We find that the JNKs are the predominant Elk‐1 activation domain kinases in extracts of UV‐irradiated cells and that immunopurified JNK1/2 phosphorylate Elk‐1 on the same major sites recognized by ERK1/2, that potentiate its transcriptional activity. Finally, we show that UV irradiation, but not serum or phorbol esters, stimulate translocation of JNK1 to the nucleus. As Elk‐1 is most likely phosphorylated while bound to the c‐fos promoter, these results suggest that UV irradiation and MEKK1 activation stimulate TCF/Elk‐1 activity through JNK activation, while growth factors induce c‐fos through ERK activation.
The Jun proteins are nuclear proteins that combine with Fos proteins to form a gene-regulatory protein, AP-1. They have highly conserved DNA-binding and dimerization domains, resulting in almost identical sequence-recognition properties. Nevertheless, there are many indications that each Jun protein activates a distinct and only partially overlapping set of AP-1 target genes. Using the more variable activation domain of c-Jun as a bait, we identified a protein, JAB1, that interacts with c-Jun and JunD, but not with JunB or v-Jun. As a result, JAB1 selectively potentiates transactivation by only c-Jun or JunD. In vitro, JAB1 specifically stabilizes complexes of c-Jun or JunD with AP-1 sites and does not affect binding of either JunB or v-Jun. The amino-terminal half of JAB1 is very similar to the amino terminal region of Pad1 from fission yeast, which was identified genetically as a coactivator of a subset of AP-1 target genes. JAB1 and Pad1 are also functionally interchangeable. They define a new group of coactivators that increase the specificity of target gene activation by AP-1 proteins.
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