Direct binding of MEK1 and MEK2 to AKT induces Foxo1 phosphorylation, cellular migration and metastasis.

Crosstalk between the ERK cascade and other signaling pathways is one of the means by which it acquires its signaling specificity. Here we identified a direct interaction of both MEK1 and MEK2 with AKT. The interaction is mediated by the proline rich domain of MEK1/2 and regulated by phosphorylation of Ser298 in MEK1, or Ser306 in MEK2, which we identified here as a novel regulatory site. We further developed a blocking peptide, which inhibits the interaction between MEK and AKT, and when applied to cells, affects migration and adhesion, but not proliferation. The specific mechanism of action of the MEK-AKT complex involves phosphorylation of the migration-related transcription factor FoxO1. Importantly, prevention of the interaction results in a decreased metastasis formation in a breast cancer mouse model. Thus, the identified interaction both sheds light on how signaling specificity is determined, and represents a possible new therapeutic target for metastatic cancer.

Role of non-phosphorylated activation loop residues in determining ERK2 dephosphorylation, activity, and subcellular localization.

Extracellular signal-regulated kinases (ERKs) activity is regulated by MAPK/ERK kinases (MEKs), which phosphorylate the regulatory Tyr and Thr residues in ERKs activation loop, and by various phosphatases that remove the incorporated phosphates. Although the role of the phosphorylated residues in the activation loop of ERKs is well studied, much less is known about the role of other residues within this loop. Here we substituted several residues within amino acids 173-177 of ERK2 and studied their role in ERK2 phosphorylation, substrate recognition, and subcellular localization. We found that substitution of residues 173-175 and particularly Pro(174) to alanines reduces the EGF-induced ERK2 phosphorylation, without modifying its in vitro phosphorylation by MEK1. Examining the ability of these mutants to be dephosphorylated revealed that 173-5A mutants are hypersensitive to phosphatases, indicating that these residues are important for setting the phosphorylation/dephosphorylation balance of ERKs. In addition, 173-5A mutants reduced ERK2 activity toward Elk-1, without affecting the activity of ERK2 toward MBP, while substitution of residues 176-8 decreased ERK2 activity toward both substrates. Substitution of Asp(177) to alanine increased nuclear localization of the construct in MEK1-overexpressing cells, suggesting that this residue together with His(176) is involved in the dissociation of ERK2 from MEKs. Combining CRS/CD motif and the activation loop mutations revealed that these two regions cooperate in determining the net phosphorylation of ERK2, but the role of the CRS/CD motif predominates that of the activation loop residues. Thus, we show here that residues 173-177 of ERK2 join other regulatory regions of ERKs in governing ERK activity.

DNA-independent PARP-1 activation by phosphorylated ERK2 increases Elk1 activity: a link to histone acetylation.

PolyADP-ribose polymerases (PARPs) catalyze a posttranslational modification of nuclear proteins by polyADP-ribosylation. The catalytic activity of the abundant nuclear protein PARP-1 is stimulated by DNA strand breaks, and PARP-1 activation is required for initiation of DNA repair. Here we show that PARP-1 also acts within extracellular signal-regulated kinase (ERK) signaling cascade that mediates growth and differentiation. The findings reveal an alternative mode of PARP-1 activation, which does not involve binding to DNA or DNA damage. In a cell-free system, recombinant PARP-1 was intensively activated and thereby polyADP-ribosylated by a direct interaction with phosphorylated ERK2, and the activated PARP-1 dramatically increased ERK2-catalyzed phosphorylation of the transcription factor Elk1. In cortical neurons treated with nerve growth factors and in stimulated cardiomyocytes, PARP-1 activation enhanced ERK-induced Elk1-phosphorylation, core histone acetylation, and transcription of the Elk1-target gene c-fos. These findings constitute evidence for PARP-1 activity within the ERK signal-transduction pathway.

DNA topoisomerase I as one of the cellular targets of certain tyrphostin derivatives.

DNA topoisomerases (topo) are the cellular targets of several anticancer drugs used today in the clinic. Our previous work demonstrated that certain tyrphostin derivatives, known as protein tyrosine kinase antagonists, are catalytic inhibitors of DNA topoisomerases I (topo I) in vitro. In this study, we examined the ability of tyrphostin derivatives to affect the activity of topo I in the cell (in vivo) and determined their in vivo mode of action. Two approaches were used; in the first, we examined the direct effect of the treatment of tumor cells with tyrphostins on the activity, level, and post-translational modifications of the cellular topo I. The second approach was to determine the influence of pretreatment of tumor cells with tyrphostin on the cellular induced effects of camptothecin (CPT), a known inhibitor of topo I. The results show that treatment of fibrosarcoma cells with tyrphostin inhibited the DNA relaxation activity of topo I but did not reduce the level of topo I protein. Tyrphostin treatments caused conformational changes of the cellular topo I probably by binding to the enzyme. Pretreatment of the cells with tyrphostin before CPT prevented the CPT-induced degradation of topo I and reduced the enzyme-DNA cleavable complexes and the ubiquitination/sumoylation of the enzyme. These data suggest that topo I is one of the cellular targets of tyrphostin and that this drug acts in vivo (in the cell) as a catalytic inhibitor of the enzyme that alters the binding of the enzyme to the DNA.

Revealing the mode of action of DNA topoisomerase I and its inhibitors by atomic force microscopy.

In this study, we used, for the first time, atomic force microscope (AFM) images to investigate the mode of action of DNA topoisomerase I (topo I) in the presence and absence of its inhibitors: camptothecin (CPT) and tyrphostin AG-1387. The results revealed that in the absence of the inhibitors, the enzyme relaxed supercoiled DNA starting from a certain point in the DNA molecules and proceeded in one direction towards one of the edges of the DNA molecule. In addition, the relaxation of the supercoiled DNA is subsequently followed by a knotting event. In the presence of CPT, enzyme-supercoiled DNA complexes in which the enzyme is locked inside a relaxed region of the supercoiled DNA molecule were observed. Tyrphostin AG-1387 altered the DNA relaxation process of topo I producing unique shapes of DNA molecules. AFM images of the topo I protein provided a picture of the enzyme, which resembles its known crystallographic structure. Thus, AFM images provide new information on the mode of action of topo I in the absence and presence of its inhibitors.